Above this text, you see the diagram of a neutron. Three quarks are forming protons and neutrons. Those quarks are connected with gluons by similar bonds that connect atoms to the entirety called molecules. Those bonds are quantum bridges. And the bonds that connect quarks and gluons are much smaller than bonds that connect atoms.
We can think that the bond between the quark and gluon is a string. And when the object is spinning that string sends wave motion like a whip. We know that things like spinning black holes are sending gravitational waves. So the form of the gravitational waves is kinetic energy.
The positronium can be a good tool for creating synthetic gravitational waves for the gravitational theory.
Image 2) Positronium could be a good tool for simulating gravitational waves. The black holes that are orbiting each other will act similar way. But of course, the energy level of black holes will be higher. And there is also an energy bridge between those black holes.
That thing could prove or close away the theory, that the origin of the gravitational waves is in the strings between quarks and gluons. When an object spins those strings will act like a whip and send the wave motion around the universe.
When two objects that are connected rotate around the mass center. They are sending wave motion. The fact is that the bond between those particles also sends wave motion to the ends of the bond.
The fact is that the bond or string between those objects travels across the quantum field it will channel wave motion to the particles at the ends of the bonds. If that thing is real. The wave motion that the source is in the particles at both ends of the string will cover the wave motion that source is the string or stick between those particles.
So when a proton or neutron spins the bond or channel that connects gluons with quarks is sending energy that it takes from the quantum field around that spinning structure. When that energy bridge or bond moves that bond acts like a whip. It sends wave motion through space. And the wavelength of that wave motion is the same as the width of the bond.
And if we are thinking of the bond between quark and gluon that string will send an extremely thin or weak wavelength. That wave motion would be hard to notice because the string that sends it is so thin. If those bonds or superstrings between quarks and gluons are the sources for gravitational waves that opens interesting visions.
https://en.wikipedia.org/wiki/Gravitational_wave
https://en.wikipedia.org/wiki/Neutron
https://en.wikipedia.org/wiki/Proton
Image 2): https://en.wikipedia.org/wiki/Positronium
https://miraclesofthequantumworld.blogspot.com/
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